Combination Umbrella and Cover

ABSTRACT

Disclosed herein is a large umbrella configured to solve several existing deficiencies. The umbrella is configured for ease of operation, requiring very little effort for operation. This is achieved, in part, by use of a specially designed actuator arm used in conjunction with at least one pulley and counterbalanced weight system. Moreover, the umbrella canopy and framework is configured to allow the entire canopy to be lowered while remaining fully extended, so as to form a cover for a table into which its center pole is situated. Additionally, the umbrella canopy can be constructed with an extendible skirt. When unfurled, the skirt can extend the canopy cover so as to form an enclosure that fully surrounds the table, table legs, and chairs, for example.

This application claims the benefit of U.S. Provisional PatentApplication No. 62/486,942 filed on Apr. 18, 2017 (pending) and U.S.Provisional Patent Application No. 62/478,592 filed on Mar. 29, 2017(pending).

BACKGROUND

Umbrellas are designed to restrict or block, for example, rain, wind,and/or sunlight. Large umbrellas typically are used on patios and decks,and at yard, courtyard, sidewalk, and beach settings. Often, largeumbrellas remain in a fixed location and typically they are constructedwith a large center pole. Many tables intended for outdoor use aredesigned to incorporate a hole in the center of the table top so as toaccept and incorporate the center pole of a large umbrella.

While there are many mechanical configurations for large umbrellas, theumbrellas remain difficult to operate. For example, significant force isrequired to extend and collapse the umbrella canopy using traditionalhand-crank/gear designs. Other configurations incorporate one or morepulleys that can be complicated to manufacture, while unsuccessfullyachieving ease of installation and/or operation. Yet other designsincorporate weights into the configuration, nevertheless requiringsignificant exertion of force on the part of the operator.

When not in use, outdoor furniture often is covered as a means ofprotecting the furniture from the elements, and to keep the furniturefree from dust, dirt, and debris. In many cases, the furniture and/orlarge umbrella incorporated therein must be dissembled in order for thefurniture to be fitted with standard outdoor furniture covers.

SUMMARY OF THE INVENTION

Disclosed herein is an umbrella configured to solve several existingdeficiencies. The umbrella is configured for ease of operation,requiring very little effort on the part of the operator, even whenconstructed as a relatively large umbrella. This is achieved, in part,by use of a specially designed actuator arm used in conjunction with atleast one pulley and counterbalanced weight system.

Moreover, the umbrella canopy and framework is configured to allow theentire canopy to be lowered while remaining fully extended, so as toform a cover for a table into which its center pole is situated.Additionally, the umbrella canopy can be constructed with an extendibleskirt. When unfurled, the skirt can extend the canopy cover so as toform an enclosure that fully surrounds the table, table legs, andchairs, for example.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows major components of the umbrella frame including theactuator, two representative struts, sliding sleeve, sliding rail, upperand lower canopy supports, and pulley mechanism, wherein the actuatorarms and the strut arms are offset at their pivot connections.

FIG. 1A shows the underside of the upper actuator arm in FIGS. 1, 4, and7 so that the upper actuator arm channel is visible.

FIG. 2 shows an upper canopy support having pairs of stays configuredfor pivotably attaching the struts and actuator corresponding to theframe design in FIG. 1.

FIG. 3 shows a lower canopy support having pairs of stays configured forpivotably attaching the struts and actuator corresponding to the framedesign in FIG. 1.

FIG. 4 shows an alternative embodiment of the major components of theumbrella frame including the actuator, two representative struts,sliding sleeve, pole, sliding rail, upper and lower canopy supports, andpulley mechanism, wherein the actuator arms are offset at their pivotconnection and the strut arms are aligned at their pivot connections.

FIG. 5 shows an upper canopy support having pairs of stays configuredfor pivotably attaching the struts and actuator corresponding to theframe design in FIG. 4.

FIG. 6 shows a lower canopy support having pairs of stays configured forpivotably attaching the struts and actuator corresponding to the framedesign in FIG. 4.

FIG. 7 shows an alternative and preferred embodiment of the majorcomponents of the umbrella frame including the actuator, tworepresentative struts, sliding sleeve, pole, sliding rail, upper andlower canopy supports, and pulley mechanism, wherein the actuator armsand strut arms are aligned at their pivot connections.

FIG. 8 shows an upper canopy support having pairs of stays configuredfor pivotably attaching the struts and actuator corresponding to theframe design in FIG. 7.

FIG. 9 shows a lower canopy support having pairs of stays configured forpivotably attaching the struts and actuator corresponding to the framedesign in FIG. 7.

FIG. 10 shows the lower actuator arm support and holes for the loweractuator arm support mount and for the lower actuator arm supportconnector.

FIG. 11 shows the lower actuator arm support in FIG. 10 mounted onto thesliding rail of the umbrella pole and having the lower actuator armpivotably connected thereto.

FIG. 12 shows detail of the umbrella pole, sliding rail, sliding sleeve,upper and lower canopy supports configured for pivotably attaching thestruts and actuator corresponding to the frame design in FIG. 7, tworepresentative struts pivotably connected between stays in the upper andlower canopy supports, the upper actuator arm pivotably connected in theupper canopy support neck groove, lower canopy support channel exposingthe sliding rail, and the upper and lower canopy support connectors forattachment to the sliding sleeve.

FIG. 13 shows major internal components of the umbrella frame locatedpartially or wholly inside the pole, including the pulley mount andmechanism, and the counterbalancing weight (not to scale).

FIG. 14 shows additional components and optional components of theumbrella, including the canopy and vent flap, tilting mechanism,valance, skirt, and finial (not to scale).

FIG. 15 shows an alternate embodiment of a lower actuator arm support.

FIG. 16 shows an alternative embodiment of the lower actuator armsupport in FIG. 15 connected to a pivotable lower actuator arm, pole,and sliding rail.

FIG. 17 shows an alternate embodiment of the sliding sleeve, uppercanopy support, and lower canopy support manufactured as a single unit.

FIG. 18 shows an alternate embodiment of a bifurcated sliding sleeve,wherein the upper portion of the sliding sleeve and the upper canopysupport are manufactured as a unit, and the lower portion of the slidingsleeve and the lower canopy support are manufactured as a unit.

FIG. 19 shows an alternate embodiment of a finial, specifically, theouter top and the inner stabilizer of a stabilizing finial (not toscale).

FIG. 20 shows the outer view of the stabilizing finial in FIG. 19 (notto scale).

FIG. 21 shows the configuration of the stabilizing finial in FIGS. 19and 20 configured such that a stabilizer base fits over the pole shownin FIGS. 1, 4, 7, 11, 12, 13, 14, 16, 17, and 18, and also such that astabilizer canal fits over the pulley shown in FIGS. 1, 4, 7, 13, and 14(not to scale).

FIG. 22 shows an alternate embodiment of a stabilizing finial,specifically, having a stabilizer slot perpendicular to the stabilizercanal, the intersection of which forms two pairs of flexible stabilizerlegs, each stabilizer leg having a stabilizer leg groove.

FIG. 23 shows the configuration of the stabilizing finial in FIG. 22(not to scale) configured such that a stabilizer canal fits over thepulley shown in FIGS. 1, 4, 7, 13, and 14, and the stabilizer slot fitsover the pulley mount shown in FIGS. 1, 4, 7, 13, and 14, and whereinthe stabilizer leg notches snap into place around the pulley mount.

FIG. 24 is a graph showing the relationship between pressure required tooperate the actuator and relative ratios of lower actuator arm lengthL_(l) to total actuator arm length L_(r).

DETAILED DESCRIPTION

The terms “a” and “an” and variations thereof represent the phrase “atleast one.” In all cases, the terms “comprising,” “comprises,”“including,” “includes,” “contains,” “having,” and any variationsthereof should not be interpreted as limited to the elements listedthereafter but rather as open-ended terms, as though the phrase “atleast” were appended thereafter.

The conjunction “or” is to be construed inclusively (i.e., one, another,or both), unless it is explicitly stated otherwise (e.g., by use of“either . . . or,” “only one of,” or similar language) or two or more oflisted alternatives are mutually exclusive within the particularcontext, in which case “or” would encompass only those combinationsinvolving non-mutually exclusive alternatives.

The term “substantially” is to be construed as meaning something thateffectively possesses the same property or achieves the same function asthat of the stated limit, and includes exactly the stated limit as wellas insignificant deviations therefrom.

The term “approximately” is to be construed as meaning something havingvery nearly the stated value, and includes exactly the stated value aswell as insignificant variations therefrom.

Unless otherwise specified, all words used herein carry their commonmeaning as understood by a person having ordinary skill in the art. Incases where examples are listed, it is to be understood thatcombinations of any of the alternative examples are also envisioned. Thescope of the invention is not to be limited to the particularembodiments disclosed herein, which serve merely as examplesrepresentative of the limitations recited in the issued claims resultingfrom this application, and the equivalents of those limitations.

Various features may be grouped together in example embodiments for thepurpose of streamlining the disclosure, but this method of disclosureshould not be interpreted as reflecting an intention that any claimedembodiment requires more features than are expressly recited in thecorresponding claim. Rather, as the appended claims reflect, inventivesubject matter may lie in less than all features of a single disclosedexample embodiment. Thus, the appended claims are hereby incorporatedinto the detailed description, with each claim standing on its own as aseparate disclosed embodiment. However, the present disclosure shallalso be construed as implicitly disclosing any embodiment having anysuitable set of one or more disclosed or claimed features (i.e., a setof features that are neither incompatible nor mutually exclusive) thatappear in the present disclosure or the appended claims, including thosesets that may not be explicitly disclosed herein. Conversely, the scopeof the appended claims does not necessarily encompass the whole of thesubject matter disclosed herein.

If the word “means” or the phrase “step for” does not appear in a claim,applicant does not intend to invoke the provisions of law relating to“means/function” or “step/function” claiming.

The abstract is provided as required as an aid to those searching forspecific subject matter within the patent literature. However, theabstract is not intended to imply that any elements, features, orlimitations recited therein are necessarily encompassed by anyparticular claim. The scope of subject matter encompassed by each claimshall be determined by the recitation of only that claim.

Certain elements of the umbrella include standard components that arereadily apparent to any person having ordinary skill in the art. Thesecomponents may be selected based upon the appropriateness of thematerials from which they are made as well as features relating to theiroverall aesthetic appeal.

For example, the umbrella typically includes a base 102. The base 102may be selected from a variety of shapes such that the overall designenables the central portion of the base 102 to accept the bottom portionof a pole 108 inserted into the top of the base 102, to extend downwardvertically into the base 102, and to be held secure. The base 102 mayinclude at least one base fitting sleeve 104 in order to accommodate apole 108 having a circumference significantly smaller than the insertionpoint in the base 102, and optionally may be fitted with a basetightening screw 106 for added security and to prevent rotation of thepole 108. The base 102 may be weighted to prevent side-to-side movementof the pole 108, especially when strong winds exert force on the canopy168. Selection of appropriate styles and materials for the base 102 arereadily apparent to any person having ordinary skill in the art. Thepole 108 comprises a cylindrical wall having inner and outer sideshaving a top portion, an elongated middle portion, and a bottom portion.

The umbrella typically includes a canopy 168 supported by struts 90, 92,as shown in FIG. 14 (not to scale). The canopy 168 may be selected froma variety of shapes such that it is fully supported by an appropriatenumber of substantially evenly spaced struts 90, 92 extending fromapproximately the outer edge of the canopy 168 periphery to the centralportion of the framework at the pole 108. The canopy 168 may bemanufactured from a variety of materials selected with regard to factorsreadily apparent to any person having ordinary skill in the art,including but not limited to overall durability, for example, sun, wind,and water resistance, overall weight, intended function, and overallaesthetic appeal. Typical materials include, but are not limited to coldrolled steel, hot rolled steel, stainless steel, and aluminum.

The canopy 168 may be supported by the struts 90, 92 in a fixed ormoveable manner. For example, the canopy 168 may be attached directlyonto the top side of the struts 90, 92, for example, by nails, screws,rivets, or bolts (not shown). The canopy 168 may have a means forreinforcement of the canopy 168 material at the point of attachment,such as metal grommets (not shown). In a preferred embodiment, thestruts 90, 92 are inserted into strut pockets (not shown) sewn into theunderside of the canopy 168 near its periphery, the pockets having theopen ends facing toward the pole 108 in order to accept the struts 90,92 radiating outward therefrom. The manner for supporting the canopy 168by the struts 90, 92 typically results in the struts 90, 92 terminatingnear the outermost periphery of the canopy 168 and serving to stretchthe canopy 168 taut when fully extended.

In some embodiments, the central pole 108 terminates at the underside ofthe canopy 168, and the canopy 168 is continuous from edge to edge. Inanother embodiment shown in FIG. 14, the central portion of the canopy168 constitutes a canopy hole 170 that is transected by the pole 108extending upward through the canopy 168, whereby the inner circumferenceof the canopy 168 rests along the struts 90, 92, and wherein the pole108 is located in the central portion of the canopy hole 170. In thiscase, a vent flap 172 is used in conjunction with the canopy 168, asdiscussed further herein.

Where a vent flap 172 is incorporated into the design, it is connectedto the top portion of the upper canopy support 148, 248, 348 by anymeans deemed reasonable by a person having ordinary skill in the art.For example, the inner portion of the vent flap 172 may be connected bya reversible means, such as with substantially evenly placed snapclosures 174. As used herein, the term “reversible” indicates that theconnection is not permanent and may be connected and disconnectedrepeatedly. The outermost edge of the vent flap 172 is partially joinedto the canopy 168. For example, the vent flap 172 typically is stitchedto the canopy 168 at substantially equal intervals close enough togetherto allow the vent flap 172 to provide protection for the area exposed bythe canopy hole 170, while allowing for circulation of air under theareas that remain unattached. Incorporation of a vent flap 172 isconsidered well within the skill of the art.

As shown in FIG. 14, the canopy 168 may include an optional skirt 178attached at the periphery of the canopy 168. The skirt may consist of asingle unit, or multiple panels that may be reversibly connected afterunfurling, for example, with one or more zippers, buttons, snaps, hooks,hook and eye connectors, hook and loop connectors, magnets, or ties (notshown). The skirt 178 may be attached to the canopy 168 in a fixed orremovable manner. For example, the skirt 178 may be sewn directly to thecanopy 168 at its periphery. In another embodiment, the skirt 178 may bereversibly attached to the canopy 168, for example, by one or morezippers, buttons, snaps, hooks, hook and eye connectors, hook and loopconnectors, magnets, or ties (not shown). In each case of attachment, itis generally considered more aesthetically pleasing for the seams orconnectors to be visible only from the underside of the canopy 168.Means and methods for attachment of a canopy skirt 178 are considered tobe readily apparent to any person having ordinary skill in the art.

It is to be understood that any such skirt 178 should extendsubstantially vertically downward from the outer periphery of the canopy168, as shown in FIG. 14. The skirt 178 may extend straight downward, orit may be designed to flare outward such that its bottom perimeter islarger than its top perimeter and/or canopy 168 perimeter. The length ofthe skirt 178 should be determined based upon its desired function. Forexample, if the skirt 178 is intended to function as a shelter frominsects, the skirt 178 should be appropriate in length to extend fromthe canopy 168 in its raised position, downward to the ground, forming atent-like structure. Where the skirt 178 is intended to operate as aprotective covering for furniture, the length of the skirt 178 should beappropriate to extend from the outer periphery of the canopy 168 in itslowered position, downward around the furniture to be protected, andonward to the ground, as shown in FIG. 14.

The skirt 178 material may be selected based upon its intended function.For example, a skirt intended to be used for protection against insectsmight be constructed from durable mesh material, e.g., mosquito netting.A skirt 178 intended to function as a protective covering for furnituremay be made of material similar to that of the canopy 168. Examples ofappropriate materials include, but are not limited to natural orsynthetic materials including cotton, canvas, nylon, and acrylic.

Optionally, such a skirt 178 can include an opening 180 in its side, asshown in FIG. 14. For example, where the skirt 178 is used as protectionfrom insects, the opening (not shown) may serve for entering and exitingthe enclosure when the skirt 178 is fully unfurled. The length of suchopening should be suitable for allowing an adult to comfortably enterand exit the enclosure. Therefore, the opening should begin at thebottom of the skirt 178 and extend an appropriate length upward.Optionally, the opening may extend vertically along the full length ofthe skirt 178, terminating near the point of attachment to the canopy168. In a skirt 178 comprised of multiple adjoining panels, each of thereversible panel connections may serve as an entryway.

In another example shown in FIG. 14, the skirt 178 is used as aprotective covering for furniture, and the opening 180 may serve toallow access to the actuator 10, 20 used to raise and lower the canopy168. In this case, the opening 180 need only extend along the portion ofthe side of the skirt 178 opposing the lower actuator arm 126, 226 (inthe lowered position) in a length appropriate to enable its access andoperation. Typically, when the lower actuator arm 126, 226 is fullylowered, the top of the opening 180 would be at or near the top of thetop of the skirt 178, and would extend downward sufficiently to enableoperation of the lower actuator arm 126, 226 upward, thus moving thecanopy 168 and skirt 178 upward as well. Once the canopy 168 and skirt178 are raised partially to an appropriate level, the operator mayremove or furl the skirt 178, and then raise the lower actuator arm 126and canopy 168 to the full upright positions. The lower actuator arm 126may be fully enclosed by the skirt 178 when they are in the loweredposition, or it may extend through the opening 180.

Useful styles of openings are readily apparent to any person havingordinary skill in the art, and may be designed according to a variety ofshapes and styles. In one embodiment, the opening is a slit having twosides of the opening meeting at their opposing edges. In anotherembodiment, the opening is a slit having two opposing sides of theopening overlapping to form a natural closure. Other embodiments maytake the form of more elaborate designs, for example, where the openinghas more than one pair of opposing sides, such as in the shape of adoor.

The opening 180 optionally may include a means for sealing or securingthe opening (not shown), such as with buttons, snaps, hooks, hook andeye connectors, hook and loop connectors, magnets, zippers, or ties.

The skirt 178 optionally may include a means for maintaining it in thedownward position (not shown). For example, weighted material may besewn into the hem along the bottom. Alternatively, the bottom hem mayinclude external fasteners, such as loops, cords, or ties for connectingto one or more stationary objects. In another embodiment, a drawstringmay be included in the hem to enable the skirt 178 to be gathered at thebottom and secured.

The skirt 178 may be retractable. Means and methods for retractingfabric are readily apparent to any person having skill in the art, andmay be accomplished manually or mechanically. For example, the skirt 178may be retracted by one or more drawstrings (not shown), such as in themanner of window blinds. Alternatively, the skirt 178 may be retractedwith a combination of sidewinders and ratchets (not shown), such as inthe manner of window shades. In another embodiment, mechanical means(not shown) for retraction may be motorized.

In the simplest of configurations, the skirt 178 may be retracted bymanually gathering, folding, and/or rolling it toward the canopy 168such that in its retracted position it is snug against the canopy 168.In a preferred embodiment, it is rolled inward and upward toward thecanopy 168 so that it is positioned on the underside of the canopy 168when it is retracted. Once retracted, the skirt 178 may be held inplace, for example, by fasteners fitted with buttons, snaps, hook andeye connectors, hook and loop connectors, hooks, or ties (not shown). Inone embodiment, the means used for securing the bottom of the skirt 178in the unfurled position may double as the means used for securing theskirt 178 to the canopy 168 in the retracted position.

The skirt 178 may be configured to roll up or fold into a closablecontainer located on the underside of the canopy 168, such as one ormore cylindrical bags (not shown). Alternatively, the container may besewn or otherwise attached to the skirt 178 itself, on the outer side atthe top near the canopy 168. Where the container is sewn onto the skirt178, it can be inverted around the skirt 178 after the skirt 178 isretracted, and optionally secured with a fastener.

The canopy 168 may include one or more valances 176 extending downwardfrom its periphery, as seen in FIG. 14. Where the canopy 168 also isattached to a skirt 178, the valance 176 is located on the outer side ofthe skirt 178. The valance 176 may be continuous as a single piece, orpresent in sections between the struts 90, 92. Valances are commonlyincluded on umbrella canopies and are obvious design choices to anyperson having ordinary skill in the art. Where a skirt 178 is attachedto the canopy 168, the valance 176 provides an aesthetic benefit ofobscuring the skirt 178 when it is in the retracted position.

As exemplified in FIG. 14, the umbrella described herein has severaladvantages when used in conjunction with a table having a central holetransecting its top, allowing for the umbrella pole 108 pass freelythrough the table top. For pedestal-style tables, the hole should extendthrough the length of the pedestal, in which case an appropriatelyshaped umbrella base should be employed. Alternately, a table pedestalmay function as the umbrella base 102. The relative size and shape ofthe canopy 168 and table top should be such that the canopy 168 extendsbeyond the outer perimeter of the table. More preferably, the canopy 168size and shape extends beyond the outer perimeter of the table as wellas any chairs that may be situated around the table.

The canopy 168 is supported by a series of substantially evenly spacedstruts 90, 92 radiating outward from the center of the frame near thepole 108, and terminating near the outer edges of the canopy 168, aspreviously described. Basic strut design is well-known and commonlyunderstood by any person having ordinary skill in the art. FIGS. 1, 4,7, and 12 show two representative struts, it being understood that oneor more additional struts would be required, and that the embodimentsdepicted in those figures requires six additional struts in the sameconfiguration as those representatively shown in the respective Figures.

The struts 90, 92 may be straight, or they may include a delicate convexarch. The number of struts 90, 92 may vary depending on the size andshape of the canopy 168. It will be appreciated by any person havingordinary skill in the art that the size, shape, and material making upthe canopy 168 will affect the optimal number of struts 90, 92 requiredto effectively support the canopy 168 and maintain it taut. Theframework should have at least three struts 90, 92, and preferably fouror more struts 90, 92. In a preferred embodiment, the framework willinclude six or more struts 90, 92. Large canopies may require eight ormore struts 90, 92. In determining the optimal number of struts 90, 92,it is preferable to employ the lowest number of struts 90, 92 thatperform the function satisfactorily, in order to minimize the overallweight of the frame. Selection of the material from which the struts 90,92 are made is well within the skill of the art, and typically includesconcern for strength and durability. Commonly used materials include,but are not limited to, steel, aluminum, wood, plastic, and resin.

In a preferred embodiment, the struts 90, 92 comprise a long upper strutarm 162, 262 pivotably connected to a short lower strut arm 160, 260.The upper 162, 262 and lower 160, 260 strut arms may be connectedadjacent to one another with a pivot connector 164, or they may beconnected centrally with a pivot connector 264 so that they are inalignment, in which case the lower strut arm 260 is connected to theunderside of the upper strut arm 262. The pivot connection 164, 264extends through both upper 162, 262 and lower 160, 260 strut arms,providing an axle about which the upper 162, 262 and lower 160, 260strut arms rotate.

Each upper strut arm 162, 262 extends from its terminus at the outeredge of the canopy 168, slightly upward toward the center of theframework at the pole 108, terminating at a pivot connection 166 withthe upper canopy support 148, 248, 348. The lower strut arm 160, 260terminates at the pivot connection 164, 264 with the upper strut arm162, 262, extends slightly downward toward the center of the frameworkat the pole 108, and terminates at a pivot connection 166 with the lowercanopy support 140, 240, 340. Thus, when the canopy 168 is fullyextended, the area bounded by the upper strut arm 162, 262, the lowerstrut arm 160, 260, the pole 108, the upper canopy support 148, 248,348, and lower canopy support 140, 240, 340 forms a triangular shape.

In order to collapse the canopy 168, the lower canopy support 140, 240,340 must be moved downward, off the sliding sleeve 136, and away fromthe upper canopy support 148, 248, 348. In so doing, the acute angleformed at the pivot connection 164, 264 of the upper 162, 262 and lower160, 260 strut arms becomes increasingly larger, nearing 180° when thecanopy 168 is fully collapsed. In this position, the upper 162, 262 andlower 160, 260 strut arms are substantially vertical and parallel to thepole 108.

Placement of the pivot connection 164, 264 for optimal performance ofthe strut 90, 92 is well within the skill of the art, and may occuranywhere along the length of the upper strut arm 162, 262. Preferablythe pivot connection 164, 264 is at a point less than half the length ofthe upper strut arm 162, 262, and more preferably at a point less thanone third the length of the upper strut arm 162, 262.

Central to the framework is a hollow pole 108 of appropriate proportionsand strength to support the rest of the frame and the canopy 168, aswell as any optional components such as a skirt 178, vent flap 172,and/or valance 176. Preferably, the pole 108 is cylindrical. The pole108 has a bottom portion having a bottom end that preferably may bepermanently mounted, planted into the ground, or inserted into astandard base 102. The elongated middle portion of the pole 108 extendsupward, optimally through the center of a table, transecting the tabletop.

The length of the pole 108 should be sufficiently long such that whenthe canopy 168 is fully extended, adult persons may freely walk uprightbeneath the canopy 168 and any valance 176. Moreover, the pole 108should be of sufficient length such that the lower strut arms 160, 260are not in the direct field of vision of persons seated at the tablewhen the canopy 168 is fully extended. The pole 108 should be ofsufficient length such that the canopy 168 may be fully collapsedwithout the outer termini of the upper strut arms 162, 262, or theperiphery of the canopy 168, coming into contact with the table top.Also, the pole 108 should be of sufficient length such that the lowercanopy support 140, 240, 340 has sufficient room to move downward alongthe pole 108 until the canopy 168 is fully collapsed.

The top portion of the pole 108 has at least one pulley opening 182 inits cylindrical wall for mounting a fixed (Class 1) pulley 184 with apulley mount 188 and allowing a cable 180 to run from the upper canopysupport 148, 248, 348, over the top of the pulley 184 toward theinternal hollow portion of the pole 108, and down the other side of thepulley 184 into the inside of the pole 108. The pulley opening 182 islocated at a height above the sliding rail 114 and the highest reachablepoint of the upper canopy support 148, 248, 348, and may be disposed toeither side of the sliding rail 114 or directly above it so long as thecable 180 does not contact the sliding rail 114. The pulley 184 may bemounted in any reasonable manner, for example, the pulley mount 188 is anut and bolt combination. Where more than one cable 180 and pulley 184pair is utilized, the pulley openings 182 in the side wall of the pole108 should be staggered in height, and situated on the wall of the pole108 in parallel, such that the pulleys 184 and cables 180 do notinterfere with one another. Preferably, the cables 180 should enter theinternal portion of the pole 108 from opposing sides. For large and/orheavy canopies and/or frames, multiple pulleys 184 may be required inorder to provide balance to the system, as shown in FIG. 13 (not toscale)

Preferably, the pulley 184 should include a guard 186 to ensure that thecable 180 does not become disengaged with the pulley 184, for example,during shipment. Pulley guards are readily apparent to any person havingordinary skill in the art and include, for example, fender guards,closed casing covers, and u-strips.

The pulley cable(s) 180 may be constructed from material appropriate forits purpose, considering factors such as strength and durability. Ropeand steel are commonly used, with steel cable being preferable. Thepulley cable(s) 180 should extend substantially vertically from the topof the upper canopy support 148, 248, 348 upward to its correspondingpulley(s) 184, as shown in FIGS. 1, 4 and 7. In a simple form ofconnection to the upper canopy support 148, 248, 348, for example, apulley cable 180 extends from the top of the upper canopy support 148,248, 348 downward through a hole (not shown) having its exit between twostay pairs 30-38, 50-58, 70-77, where the end of the cable 180 is fixedwith a crimp (not shown). In an alternate embodiment, the hole in theupper canopy support 148, 248, 348 (not shown) for accepting the cable180 may be placed closer to the inner edge of the upper canopy support148, 248, 348, extending from the top of the upper canopy support 148,248, 348 downward through the neck 150, 250 of the upper canopy support148, 248, 348 to the underside of the upper canopy support 148, 248,348, where the cable 180 is permanently connected by any reasonablemeans, including, but not limited to a crimp (not shown).

As shown in FIG. 13 (not to scale) the cable 180 extends verticallydownward from the top of the pulley 184 through the void in the pole 108and is connected to a single weight 190 configured to easily move up anddown inside the pole 108. Where more than one pulley 184 and cable 180pair is utilized, they should operate without interfering with oneanother. Therefore, multiple cables 180 should extend from differentpoints on the top of the upper canopy support 148, 248, 348, over theirrespective pulleys 184, and downward though the hollow of the pole 108to be attached to the single weight 190. The cables 180 may be connectedto the weight 190 by any reasonable means, for example, with an eyebolt. The weight 190 attached to the cable(s) 180 is substantially equalto the combined weight of the canopy 168, struts 90, 92, upper and lowercanopy support 140, 240, 340, sliding sleeve 136, vent flap 172 (ifany), valance 176 (if any), skirt 178 (if any), and optional ballastweights 192.

The weight 190 located internally in the pole 108 is intended tocounterbalance the combined weight of the components that are raised andlowered by the actuator 10, 20. The combined weight of the componentsmay be variable, however. For example, a wet canopy 168 may weigh morethan a dry canopy 168. Different skirt 178 attachments may weigh more orless than one another. Dirt and dust may build up on the pulleys 184over time, or wear on the pulley(s) 184 and/or cable(s) 180 may increasefriction, requiring adjustment of the counterbalanced weight in order tomaintain ease of operation of the actuator 10, 20. An optional set ofballast weights 192 may be included to make adjustments to the combinedweight of the components to be raised and lowered by the actuator 10, 20such that it remains substantially counterbalanced with the weight 190inside the pole 108.

The ballast weights 192 may be attached by any reasonable means to anyof the other components making up the combined counterbalanced weight,so long as they do not interfere with any of the intended functions ofthose components. Preferably, the ballast weights 192 are located on theupper canopy support 148, 248, 348, and more preferably on or near thetop of the upper canopy support 148, 248, 348 as shown in FIG. 12.

The optimized actuator 10, 20 working in conjunction with thecounterbalanced weight system provides an elegant and simple designrequiring very little effort to operate, regardless of the size andweight of the canopy 168 and supporting framework.

The uppermost end of the pole 108 should be fitted with a cap in thecase where the pole 108 terminates on the underside of the canopy 168.Where the pole 108 extends through a canopy hole 170, the uppermost endof the pole 108 may be fitted with a decorative finial. The cap orfinial 197 prevents moisture, dirt, dust, and debris from entering theinner portion pole 108 and prevents exposure of sharp edges, as well asadding a decorative feature. These features are well-known within thestate of the art.

FIGS. 19, 20, and 21 show an alternate embodiment of a stabilizingfinial 400 having a stabilizing finial base 402 and a stabilizing finialtop 404. The stabilizing finial top 404 extends from its inner, upperportion downward to form a stabilizing finial plug 407 havingsubstantially the same shape and size as the pole 108. The stabilizingfinial plug 407 extends further downward to form a stabilizer 408,having a slightly smaller perimeter than the stabilizing finial plug407, so as to enable insertion of the stabilizer 408 into the pole 108.The interface of the smaller stabilizer 408 and the larger stabilizingfinial plug 407 forms a sealing edge 409 that abuts the top of the pole108. The bottom portion and one side of the asymmetrical stabilizer 408include a stabilizer canal 410 having substantially the same shape asthe upper portion of a pulley 184, such that when the stabilizing finial400 is attached to the pole 108, the stabilizing finial plug 407 restsatop the pole 108 at the sealing edge 409, the stabilizer 408 isinserted into the inner portion of the pole 108, and the stabilizercanal 410 fits over and around the upper portion of the uppermost pulley184. The remainder of the inner portions of the stabilizing finial base402, and stabilizing finial top 404 are recesses around the stabilizingfinial plug 407, stabilizer 408, and sealing edge 409. Thus, when thestabilizing finial 400 is inserted into the pole 108, the stabilizingfinial base 402 extends downward along the outer portion of the pole108.

When the stabilizing finial is inserted into the pole 108, thestabilizer 408 and stabilizer canal 410 maintains the cable 180 on theuppermost pulley 184, thus eliminating the need for a pulley guard 186,and serves to keep the pulley 184 stabilized. The finial plug 407 andsealing edge 409 prevent debris and moisture from entering the innerportion of the pole 108.

FIGS. 19, 20, and 21 (not to scale) show an embodiment of thestabilizing finial 400 in which the stabilizer canal 410 is centrally,albeit asymmetrically configured in the stabilizer 408 for use with asingle-pulley configuration. In the case of a multiple-pulley system,the stabilizer canal 410 would be offset to one side of theasymmetrically configured stabilizer 408 to accommodate the adjacentlysituated pulleys 184.

FIGS. 22 and 23 (not to scale) show an alternate embodiment of astabilizing finial 600 having a modified stabilizer 608 in which thestabilizer canal 610 extends fully across the stabilizer 608. Thestabilizer canal 610 fits over and around the upper portion of theuppermost pulley 184. For example, in a single pulley configuration, thestabilizer canal 610 may be situated substantially centrally in thestabilizer 608. In a multi-pulley configuration having the pulleysoffset in parallel from one another, as previously described, thestabilizer canal 610 may be offset to fit over the uppermost pulley 184.A stabilizer slot 673 runs perpendicular to and intersects thestabilizer canal 610, forming two pairs of flexible stabilizer legs 675,676. Each pair of stabilizer legs 675, 676 is symmetrically opposed toone another. The stabilizer slot 673 is positioned in the stabilizer 608so that it extends into the pole 108, and down past the uppermost pulleymount 188 to fit securely around it, with a pair of symmetricalstabilizer legs 675, 676 situated on either side. Because the pulley 184extends through the pulley opening 182, the pulley mount 188 and thestabilizer slot 673 are typically offset from center in the stabilizer608. Each pair of stabilizer legs 675, 676 have opposing stabilizer leggrooves 677. The stabilizer leg grooves 677 snap into place around theuppermost pulley mount 188. The stabilizer legs 675, 676 are slightlyinset and the total circumference of the stabilizer legs 675, 676 takentogether is smaller than the top portion of the stabilizer 608, therebyforming a stabilizer ridge 611 on the underside of the cylindrical upperportion of the stabilizer 608 where the stabilizer legs 675, 676, thestabilizer slot 673, and the stabilizer canal 610 are adjacent. This isso that the stabilizer legs 675, 676 can flex outward when being snappedinto place around the pulley mount 188, and avoid being vertically flushagainst the inner side of the pole 108.

A sliding rail 114 runs vertically along the length of the pole 108,from its connection to the lower actuator arm support 120 at about thetop of the bottom portion of the pole 108 to the top of the upper canopysupport 148, 248, 348 when the canopy 168 is in the raised position, asseen in FIGS. 1, 4, 7, 11, 12, and 14. The top of the sliding rail 114is located at about the bottom of the top portion of the pole 108, andthe bottom of the sliding rail 114 and lower actuator arm support 120are located at about the top of the bottom portion of the pole 108. Thesliding rail 114 bears a notch 116 for accepting the pivotable connectorjoining the upper 128, 228 and lower 126, 226 actuator arms, when theactuator 10, 20 is in the raised position, as more fully describedherein. The notch 116 should be appropriate to allow the upper actuatorarm 228 to rest flush against the sliding rail 114 when the actuator 10,20 is in the raised position, but it should not interfere with themobility of the sliding sleeve 136. The sliding rail 114 guides thesliding sleeve 136 when it is raised and lowered via operation of theactuator 10, 20, and stabilizes the upper 148, 248, 348 and lower 140,240, 340 canopy supports, preventing them from turning about the pole108.

The pole 108 and sliding rail 114 optionally may include a tiltingmechanism 118 for arranging the canopy 168 at different angles andpositions relative to the ground. Various tilting mechanisms 118 arecommon in the art and include, for example, knuckle tilts. The tiltingmechanism 118 should form a smooth interface with the pole 108 andsliding rail 114 when not employed, enabling the sliding sleeve 136 topass over it freely. The tilting mechanism 118 should be located belowthe lower canopy support 140, 240, 340 when the canopy is in the raisedposition, as shown in FIG. 14.

The pole 108 may include an upper stop tab 110 and a lower stop tab 112,as shown in FIG. 1. The upper stop tab 110 is located below the lowestpulley 184, and prevents the upper canopy support 148, 248, 348 fromcoming into contact with it. The lower stop tab 112 is located at thebottom of the lower canopy support 140, 240, 340 when the actuator 10,20 is in the lowered position, and acts to prevent harm to the loweractuator arm 126, 226 from a pivot of greater than 90 degrees relativeto the pole 108.

The framework includes an actuator 10, 20 for raising and lowering thecanopy 168 while it is in the extended position. The actuator 10, 20comprises a lower actuator arm 126, 226 joined to an upper actuator arm128, 228 by a pivot connection 130, 230 extending through both actuatorarms 126, 128; 226, 228. The pivot connection forms an axle about whichthe actuator arms 126, 128; 226, 228 rotate. The upper 128 and lower 126actuator arms may be pivotably connected adjacent to one another, or theupper 228 and lower 226 actuator arms may be pivotably connectedcentrally so that they are in alignment, in which case the upperactuator arm 228 is connected to the top side of the lower actuator arm226, in the lower actuator arm channel 132, as shown in FIG. 7.

As shown in FIGS. 1, 4, and 7 and in greater detail in FIGS. 10 and 11,the lower actuator arm 126, 226 is pivotably connected to a loweractuator arm support 120 mounted to the sliding rail 114 by a fixedconnection 124, such as a bolt extending through the lower actuator armsupport mounting hole 122 and sliding rail 114, and optionally, alsothrough the adjacent wall of the pole 108. The lower actuator armsupport connector 124 is a pivot connection extending through the loweractuator arm 126, 226 to provide an axle about which the lower actuatorarm 126, 226 rotates. The lower actuator arm support 120 is mounted tothe sliding rail 114 at a position that is above the top surface of thetable through which the pole 108 passes, such that when the loweractuator arm 126, 226 is in the lowered position, it extends outwardfrom the pole 108 substantially at a 90° angle a short distance abovethe table. The lower actuator arm 126, 226 extends outward and is ofsufficient length to enable its operation without the operator becomingencumbered by the canopy 168 as it is lowered. The upper actuator arm128, 228 terminates at one end at the pivot connection 130, 230 with thelower actuator arm 126, 226, and extends to the upper canopy support148, 248, 348. The upper actuator arm 128, 228 may be pivotably attachedto the upper canopy support 148, 248, 348, for example, between a pairof stays 38, 58. More preferably, the upper actuator arm 128, 228 ispivotably attached to the upper canopy support 148, 248, 348 at the neck150, 250 or bottom of the support. Additionally, the end of the upperactuator arm 128, 228 and the pivot connection (not visible) may berecessed into a groove 156 in the wall of the neck and/or bottom of theupper canopy support 148, 248, 348. The pivot connection extends throughthe upper actuator arm 128, 228, providing an axle about which itrotates. Thus, when the actuator 10, 20 is fully lowered, the areabounded by the upper actuator arm 128, 228, the lower actuator arm 126,226, the pole 108, and the upper canopy support 148, 248, 349 forms asubstantially triangular shape.

FIGS. 15 and 16 show alternate embodiments of the lower actuator armsupport 220. The lower actuator arm support 220 may be connecteddirectly to the pole 108, for example, by welding. This embodimenteliminates the need for the collar portion of the support around thepole 108. The lower actuator arm support 220 may be mounted to thesliding rail 114 at a position that is above the top surface of thetable through which the pole 108 passes, such that when the loweractuator arm 126, 226 is in the lowered position, it extends outwardfrom the pole 108 substantially at a 90° angle a short distance abovethe table. Alternatively, the lower actuator arm support 220 may beconfigured as a solid block having an optional support mounting hole 222for accepting an optional fixed connector, such as a bolt extendingthrough the lower actuator arm support mounting hole 222 and pole 108.When configured as a single block, the lower actuator arm support 220 issituated at the terminal bottom portion of the sliding rail 114 atinterface 225. The sliding rail 114 may be shorter in length when thelower actuator arm support 220 is configured as a block, in which casethe sliding rail 114 is not situated in the recess of the lower actuatorarm support adjacent to the pole 108. Alternatively, the lower actuatorarm 220 block configuration may be situated lower on the pole 108,provided that when the lower actuator arm 126, 226 is in the loweredposition, it extends outward from the pole 108 substantially at a 90°angle a short distance above the table. Lower actuator arm support 220includes a hole for accepting a lower actuator arm support connector124.

Proper determination of the relative lengths of the upper 128, 228 andlower 126, 226 actuator arms and placement of the actuator arm pivotconnection 130, 230 is important to the overall design. These factorsimpact the overall ease of operation and the amount of force required bythe operator to move the actuator 10, 20. Optimal placement of the pivotconnection 130, 230 is capable of resulting in less than one pound ofpressure required to move the canopy 168 using the actuator 10, 20.

As discussed herein, when the actuator 10, 20 is in the raised position,the portion of the lower actuator arm 126 extending outward past thepivot connection 130 overlaps with the upper actuator arm 128 whenadjacently connected. Likewise, when the actuator 10, 20 is in theraised position, the portion of the portion of the lower actuator arm226 extending outward past the pivot connection 230 folds over the upperactuator arm 228 when centrally connected, whereby the upper actuatorarm 228 fits into the lower actuator arm channel 132. Therefore, thetotal length of the actuator 10, 20 in the raised position (L_(r)) isthe sum of the lengths of the lower actuator arm 126, 226 measured fromthe pivot connection 130, 230 to the lower actuator arm supportconnection 124 (L_(l)), and the upper actuator arm 128, 228 measuredfrom the pivot connection 130, 230 to its connection with the uppercanopy support 148, 248, 348 (L_(u)). Therefore, L_(r)=L_(l)+L_(u).

Adjusting the relative L_(l) and L_(u) ratio affects the amount ofpressure required to operate the actuator 10,20. As shown in FIG. 24, itis preferable for L_(l) to be about 43-47% of L_(r), and more preferablyabout 44-46% of L_(r), and even more preferably about 45% of L_(r).

As the actuator 10, 20 is raised, the angle formed at the pivotconnection 130, 230 of the upper 128, 228 and lower 126, 226 actuatorarms becomes increasingly large, nearing 180° when the actuator 10, 20is fully raised. In this position, the actuator arms 126, 128; 226, 228are substantially vertical and parallel to the pole 108.

When the actuator 10, 20 is in the raised position, the upper actuatorarm 128 may lay against the outer side of the lower canopy support 140,240 between pairs of stays 40, 47; 60, 67 supporting lower strut arms160, 260, as shown in FIGS. 3 and 6. Alternatively, the lower canopysupport 340 may be designed having a vertical slice removed so as toform a channel 343 running from its top to its bottom and exposing thesliding rail 114, thus enabling the upper actuator arm 228 to passthrough the lower canopy support 340, as shown in FIG. 9. The canopysupports are configured in accordance with whether the strut arms 160,162; 260, 262 and/or actuator arms 126, 128; 226, 228 are adjacently orcentrally connected. In some configurations, the actuator 20 may opposethe sliding rail 114 when in the raised position, and in otherconfigurations the actuator 10 may be in a position adjacent to thesliding rail 114.

In a preferred embodiment, the upper 228 and lower 226 actuator arms arepivotably connected centrally and in alignment with the sliding rail114, as shown in FIGS. 7, 8, 9, and 12. Both actuator arms 226, 228contain a channel 132, 134 running along their lengths and opposing oneanother. The channel 132 in the lower actuator arm 226 faces upward,while the channel 134 in the upper actuator arm 228 faces downward. FIG.1A shows the underside of the upper actuator arm shown in FIG. 7 so thatthe channel 134 is visible. The width of the lower actuator arm 226 ispreferably wider than that of the upper actuator arm 228 such that whenthe arms are centrally connected, the upper actuator arm 228 folds intothe channel 132 in the lower actuator arm 226 when they are in theraised position. Likewise, the width of the upper actuator arm 228 ispreferably wider than that of the sliding rail 114 such that when theactuator 20 is in the raised position, the upper actuator arm 228accepts the sliding rail 114 into its channel 134, resulting in a snugfit of the actuator 20 against the pole 108.

The lower actuator arm 126, 226 may include a handle 198 on itsunderside, at the outer end for maximum leverage. When the actuator 10,20 is in the raised position, this handle 198 is used to guide theactuator 10, 20 downward, thus raising the internal weight 190 in thepole 108 and lowering the canopy 168.

A magnet 196 may be placed near the handle 198, on the underside of theouter end of the lower actuator arm 126, 226. Depending on the strengthof the magnet 196 and the method of placement on the lower actuator arm126, 226, it may be preferable to position a hole (not shown) in thelower actuator arm 126, 226 opposite the magnet 196. The magnet 196attracts the upper actuator arm 126, 228 when the actuator 10, 20 is inthe raised position, thus securing the position and preventing anydownward drift of the actuator 10, 20 resulting from the substantiallycounterbalanced weight system, especially on windy days when the canopy168 may be shifting.

A lower actuator arm fastener (not shown) may be used to secure thelower actuator arm 126, 226 to the table and to maintain it in thelowered position, especially in windy conditions. In one embodiment, thehandle 198 may be configured to attach to the peripheral edge of thetable or underside thereof, where the table top is of sufficientdiameter for its outer edges to terminate at or near the handle 198.Alternatively, a separate fastener may be attached to the lower actuatorarm 126, 226 in a manner that does not interfere with the function ofthe lower actuator arm channel 132. Preferably, the fastener is movablealong the lower actuator arm 126, 226, and it is adjustable in length toaccommodate for table tops of various size and height. As an exemplaryembodiment, a strap, bungee cord, or tie-down adjustable in position andlength is attached to the lower actuator arm 126, 226. The other end ofthe strap terminates in a wide hook, the tip of which is placed on theunderside of the table at the peripheral edge. In another embodiment, acarabiner is used rather than a hook, which may be attached to theunderside of the table on existing framework or with a specially placedloop. Any suitable fastener mechanism may be used, such as a pin andhole, clasp mechanism, latch mechanism, etc.

The upper strut arms 162, 262 extend from the outer edges of the canopy168 converging toward the pole 108, terminating at substantially evenlyspaced pivot connections 166 to the upper canopy support 148, 248, 348.The lower strut arms 160, 260 extend from their pivot connections 164,264 with their corresponding upper strut arms 162, 262, convergingtoward the pole 108 and terminating at substantially evenly spaced pivotconnections 166 with the lower canopy support 140, 240, 340. The pivotconnections 166 extend through the upper 162, 262 and lower 164, 264strut arms, forming axles about which the upper 162, 262 and lower 164,264 strut arms rotate. FIG. 9 shows a representative pivot connection166.

Canopy supports come in a wide variety of shapes and styles, all ofwhich are readily apparent to any person having ordinary skill in theart. The upper 148, 248, 348 and lower 140, 240, 340 canopy supportsshould have an inner surface shape substantially the same as that of thepole 108. In a preferred embodiment, the inner surface shape issubstantially cylindrical to fit a cylindrical pole 108, and includes arail groove 146, 154 to accommodate a sliding rail 114. The innersurface of the upper 148, 248, 348 and lower 140, 240, 340 canopysupports have a diameter slightly larger than that of the combined pole108 and sliding sleeve 136, as described further herein, to enableattachment to the sliding sleeve 136 situated between the upper 148,248, 348 and lower 140, 240, 340 canopy supports and the pole 108.

The outer configuration of the upper 148, 248, 348 and lower 140, 240,340 canopy supports should be sufficient to reasonably enable permanentattachment of one or more pulley cables 180 to the upper canopy support148, 248, 348, and pivotable attachment of substantially evenly spacedupper 162, 262 and lower 164, 264 strut arms to the upper 148, 248, 348and lower 140, 240, 340 canopy supports. In the case of the upper canopysupport 148, 248, 348, its configuration also should enable pivotableattachment of the upper actuator arm 128, 228, as described more fullyherein The upper 148, 248, 348 and lower 140, 240, 340 canopy supportseach may include a neck portion 150, 142; 250, 242 at their respectivebases.

In one embodiment, each upper 162, 262 and lower 164, 264 strut arm ispivotably connected between a pair of stays 30-38, 40-47, 50-58, 60-67,70-77, 80-87 radiating outward from the central portion of the upper andlower 140, 240, 340 canopy supports. In this embodiment, the distancebetween the stays 30-38, 40-47, 50-58, 60-67, 70-77, 80-87 in each pairis slightly larger than the width of the corresponding upper 162, 262 orlower 164, 264 strut arm, enabling freedom of movement of the upper 162,262 and lower 164, 264 strut arm around the strut arm stay connectors166 while also providing stability. The strut arm stay connectors 166extend through both stays in the stay pair 30-38, 40-47, 50-58, 60-67,70-77, 80-87 and the corresponding upper 162, 262 and lower 164, 264strut arm. Each stay pair 30-38, 40-47, 50-58, 60-67, 70-77, 80-87 andupper 162, 262 or lower 164, 264 strut arm combination may have aseparate pivot connector 166. In an alternate embodiment, a single pivotconnector, for example a ring-shaped connector (not shown), may form acontinuous connector for all of the upper 162, 262 and lower 164, 264strut arm/stay pair 30-38, 40-47, 50-58, 60-67, 70-77, 80-87combinations. In another embodiment, the area between each stay pair30-38, 40-47, 50-58, 60-67, 70-77, 80-87 constitutes an outwardextension of the central portion of the canopy support so as toaesthetically hide the pivot connection(s) and to minimize theappearance of the protruding stays.

In one embodiment, the upper actuator arm 128 is pivotably connected tothe upper canopy support 148, 248 between a pair of stays 38, 58 at thesame level as the upper strut arm stay pairs 30-37, 50-57 correspondingto the upper strut arms 162, 262. In another embodiment, the upperactuator arm 128, 228 is pivotably connected to a side of the neck 150,250 portion of the upper canopy support 348 at a level lower than thestrut arm stay pairs 30-37, 50-57 corresponding to the upper strut arms162, 262, either directly on the wall of the neck 150, 250 or between anadditional pair of stays (not shown). In another embodiment, the upperactuator arm 128, 228 is pivotably connected to the upper canopy supporton the bottom of the neck 150, 250 of the upper canopy support 348.Additional embodiments include pivotal connection of the upper actuatorarm 128, 228 recessed in an upper canopy support neck groove 156 on theside of and/or or under the upper canopy support neck 150, 250. In thisembodiment, an upper canopy support neck groove pivot connector extendshorizontally from one side of the upper canopy support neck 150, 250,through the neck groove 156 and the upper actuator arm 128, 228, to theopposing side of the upper canopy support neck 150, 250. The uppercanopy neck groove connector forms an axle about which the upperactuator arm 128, 228 rotates.

Placement of the stay pairs 30-38, 40-47, 50-58, 60-67, 70-77, 80-87 andstrut arm stay pivot connectors 166 for the upper 162, 262 and lower160, 260 strut arms on the upper 148, 248, 348 and lower 140, 240, 340canopy supports depends on: a) the number of substantially evenly spacedstruts 90, 92 around the circumference of the upper 148, 248, 348 andlower 140, 240, 340 canopy supports; b) the location of the connectionof the upper actuator arm 128, 228 to the upper canopy support 148, 248,348; and whether the strut arms 160, 162; 260, 262 and/or actuator arms126, 128; 226, 228 are pivotably connected adjacently or centrally.

In an example shown in FIGS. 2 and 3, the upper 148 and lower 140 canopysupports are configured to accommodate eight struts 90, each comprisedof upper 162 and lower 160 strut arms joined adjacently at pivotconnection 164, the actuator 10 is comprised of upper 128 and lower 126actuator arms joined adjacently at pivot connection 130, and the upperactuator arm 128 is connected to the upper canopy support 148 between astay pair 38 at the same level as those used with the upper strut arms162. In this example, the position of the upper actuator arm 128 isrepresented by X, which is pivotably connected between stay pair 38, andthe upper strut arms 162 are pivotably connected to the upper canopysupport 148 at positions A-H between stay pairs 30-37. The lower strutarms 160 are pivotably connected to the lower canopy support 140 atpositions a-h between stay pairs 40-47, which are offset from positionsA-H and stay pairs 30-37 to accommodate for the adjacent pivotconnection 164 of the upper 162 and lower 160 strut arms. When theactuator 10 is in the raised position, the upper actuator arm 128 restsalong the outer side of the lower canopy support 140. In this example,the lower canopy support 140 is configured to accommodate the upperactuator arm 128 at position X when it is in the raised position.

In an example shown in FIGS. 5 and 6, the upper 248 and lower 240 canopysupports are configured to accommodate eight struts 92 comprised ofupper 262 and lower 260 strut arms centrally joined at pivot connection264, the actuator 10 is comprised of upper 128 and lower 126 actuatorarms adjacently joined at pivot connection 130, and the upper actuatorarm 128 is connected to the upper canopy support 248 between a stay pair58 at the same level as the upper strut arms 262. In this example, theupper actuator arm 128 is pivotably connected between stay pair 58, andthe upper strut arms 262 are pivotably connected to the upper canopysupport 248 between stay pairs 50-57. The lower strut arms 260 arepivotably connected to the lower canopy support 240 between stay pairs60-67. When the actuator 10 is in the raised position, the upperactuator arm 128 rests along the lower canopy support 240. In thisexample, the lower canopy support 240 is configured to accommodate theupper actuator arm 128 in the raised position.

In an example shown in FIGS. 8 and 9, the upper and lower 340 canopysupports are configured to accommodate eight struts 92 comprised ofupper 262 and lower 260 strut arms connected centrally at pivotconnection 264, the actuator 20 is comprised of upper 228 and lower 226actuator arms joined centrally at pivot connection 230, and the upperactuator arm 228 is connected to the upper canopy support 348 in theupper canopy support neck groove 156, at a level below the upper strutarms. In this example, the upper canopy support neck groove pivotconnection of the upper actuator arm 228 to the upper canopy support 348is not visible, and the upper strut arms 262 are pivotably connected tothe upper canopy support 348 at positions A-H between stay pairs 70-77.The lower strut arms 260 are pivotably connected to the lower canopysupport 340 at positions a-h between stay pairs 80-87. Thisconfiguration shows a vertical slice extending through the lower canopysupport 340 to create lower canopy support channel 343 exposing thesliding rail 114 through the lower canopy support channel 343. Theactuator 20 is positioned so that when it is in the raised position, itrests in the channel 343 of the lower canopy support 340, with thesliding rail 114 in the upper actuator arm channel 134.

In view of the foregoing non-restrictive examples, it should beappreciated that any person having ordinary skill in the art couldconfigure an appropriate pair of upper and lower 140, 240, 340 canopysupports based upon the disclosure herein.

The upper canopy support 148, 248, 348, the lower canopy support 140,240, 340, and the sliding sleeve 136 are connected such that thedistance between the upper 148, 248, 348 and lower 140, 240, 340 canopysupports remains fixed, enabling operation of the actuator 10, 20 toresult in raising and lowering of the canopy 168 while it remains fullyextended. The sliding sleeve 136 should be substantially the same shapeas the pole 108 except that it is discontinuous, having a verticalchannel 138 along its entire length to expose the sliding rail 114. Theinner circumference of the sliding sleeve 136 is slightly larger thanthat of the pole 108 around which it is fitted, to enable the sleeve toslide freely along the pole 108. The width of the sliding sleeve channel138 is slightly larger than the width of the sliding rail 114.

As shown in FIG. 12, the upper canopy support 148, 248, 348 is connectedto the sliding sleeve 136 with at least one reversible upper canopysupport connector 152, for example, a screw. In embodiments wherein thelower canopy support 140, 240 is continuous, it may be connected to thesliding sleeve 136 in the same manner as the upper canopy support 148,248, 348. In embodiments wherein the lower canopy support 340 includes alower canopy support channel 343, at least two reversible lower canopysupport connectors 244 should be employed on either side of the channel343. The length of the upper 152 and lower 144, 244 connectors should beshort enough so as not to come into contact with the pole 108.

It may be preferable to use a quick-release means for the lower canopysupport connector(s) 244, as it/they must be removed in order to slidethe lower canopy support 140, 240, 340 off the sliding sleeve 136 and toincrease the distance between the upper 148, 248, 348 and lower 140,240, 340 canopy supports, thereby collapsing the canopy 168.

When the upper 148, 248, 348 and lower 140, 240, 340 canopy supports areconnected to the sliding sleeve 136, the sliding sleeve 136 shouldextend from the top of the upper canopy support 148, 248, 348 to thebottom of the lower canopy support 140, 240, 340. The length of thesliding sleeve 136 and the corresponding distance between the upper 148,248, 348 and lower 140, 240, 340 canopy supports is determined prior toconnecting the upper 148, 248, 348 and lower 140, 240, 340 canopysupports to the sliding sleeve 136. The upper 148, 248, 348 and lower140, 240, 340 canopy supports should be situated on the pole 108, andall of the upper 162, 262 and lower 160, 260 strut arms should beconnected thereto. By fully extending the canopy 168, the struts 90, 92guide the upper 148, 248, 348 and lower 140, 240, 340 canopy supports totheir proper positions for maintaining full extension of the canopy 168.The distance between the upper 148, 248, 348 and lower 140, 240, 340canopy supports can be recorded, and the length of the sliding sleeve136 determined accordingly.

When the upper 148, 248, 348 and lower 140, 240, 340 canopy supports areconnected to the sliding sleeve 136, they operate as a single unitsliding up and down the pole 108 in response to operation of theactuator 10, 20.Once the distance between the upper canopy support 448and lower canopy support 440 is determined, they may be manufacturedtogether with the sliding sleeve 436 as a single unit, as shown in FIG.17. In this embodiment, the distance between the upper 448 and lower 440canopy supports remain fixed, and the canopy 168 cannot be collapsed.The need for upper canopy support connector 152 and lower canopy supportconnector(s) 144, 244 is eliminated. Alternatively, the upper canopysupport neck 450 is extended as sliding sleeve 436 and joined to the topof the lower canopy support 440.

In yet another embodiment shown in FIG. 18, the sliding sleeve isbifurcated. The upper portion of the sliding sleeve 536 a ismanufactured as a single piece together with upper canopy support 548,and the lower portion of the sliding sleeve 536 b is manufacturedtogether as a single piece together with lower canopy support 540. Thebottom of sliding sleeve 536 a and top of sliding sleeve 536 b meet atbifurcated sliding sleeve interface 537. Alternatively, the upper canopysupport neck 550 is extended as sliding sleeve 536 a and the top of thelower canopy support 540 is extended as sliding sleeve 536 b so that thebottom of sliding sleeve 536 a and top of sliding sleeve 536 b meet atbifurcated sliding sleeve interface 537. When sliding sleeves 536 a and536 b meet at the bifurcated sliding sleeve interface 537, the totallength of the sliding sleeves 536 a and 536 b maintains the properdistance between the upper canopy support 548 and the lower canopysupport 540. This two-piece design allows the two portions of thesliding sleeve 536 a and 536 b to be separated, enabling the canopy 168to be collapsed. This embodiment also eliminates the need for uppercanopy support connector 152 and lower canopy support connector(s) 144,244. However, the two portions of the sliding sleeve 536 a and 536 bmeeting at the bifurcated sliding sleeve interface 537 must bemaintained in place when the canopy 168 is raised. This is accomplishedby using a bifurcated sliding sleeve connector 539 of any reasonableconfiguration, such as one that joins the two portions directly, exampleof which include, but are not limited to a clasp mechanism, a latchmechanism, magnetic connectors, nut and bolt pair, etc. Alternatively, abifurcated sliding sleeve connector 539 includes configurations thatattach each of the two portions of the sliding sleeve 536 a and 536 bindependently to the pole 108 in the proper so that they meet at thebifurcated sliding sleeve interface 537, examples of which include, butare not limited to screws, pins, adjustable collars, etc. In oneexample, shown in FIG. 18, the two portions of the sliding sleeve 536 aand 536 b meeting at the bifurcated sliding sleeve interface 537 aremaintained in place using a latch mechanism, each opposing portion ofthe latch mechanism being situated on either side of the bifurcatedsliding sleeve interface 537 on the respective portions of the slidingsleeve 536 a and 536 b.

COMPONENT LIST

Ref. No. Component 102 Base 104 Base fitting sleeve 106 Base tighteningscrew 108 Pole 110 Upper stop tab 112 Lower stop tab 114 Sliding rail116 Sliding rail notch 118 Tilting mechanism 120, 220 Lower actuator armsupport 122, 222 Lower actuator arm support mounting hole 124 Loweractuator arm support connector 126, 226 Lower actuator arm Not shownLower actuator arm fastener 128, 228 Upper actuator arm 130, 230Actuator arm pivot connector 132 Lower actuator arm channel 134 Upperactuator arm channel 10, 20 Actuator 136, 436 Sliding sleeve 138 Slidingsleeve channel 140, 240, 340, 440, 540 Lower canopy support 142, 242,442, 542 Lower canopy support neck 343 Lower canopy support channel 144,244 Lower canopy support connector(s) 146 Lower canopy support railgroove 148, 248, 348, 448, 548 Upper canopy support 150, 250, 450, 550Upper canopy support neck 152 Upper canopy support connector 154 Uppercanopy support rail groove 156 Upper canopy support neck groove Notshown Upper canopy support neck groove connector Not numbered Staysindividually 30-38, 40-47, Stay pairs 50-58, 60-67, 70-77, 80-87 160,260 Lower strut arm(s) 162, 262 Upper strut arm(s) 90, 92 Strut(s) 164,264 Strut arm pivot connector(s) 166 Strut arm stay connector(s) 168Canopy 170 Canopy hole Not shown Strut pockets(s) 172 Vent flap 174 Ventflap snap closures(s) 176 Valence 178 Skirt Not shown Skirt secure(s)Not shown Skirt attachment 180 Skirt opening Not shown Skirt hem Notshown Skirt hem secure(s) Not shown Skirt container(s) 180 Cable(s) Notshown Cable connectors(s) 182 Pulley opening(s) 184 Pulley(s) 186 Pulleyguard(s) 188 Pulley mount(s) 190 Weight 192 Ballast weight(s) 194Ballast connector(s) 196 Magnet Not shown Magnet hole 197 Finial/cap 198Handle 225 Lower actuator arm/sliding rail interface 537 Bifurcatedsliding sleeve interface 539 Bifurcated sliding sleeve connector  536aBifurcated sliding sleeve upper portion  536b Bifurcated sliding sleevelower portion 400, 600 Stabilizing finial 402 Stabilizing finial base404 Stabilizing finial top 406 Stabilizing finial inner recess 407Stabilizing finial plug 408, 608 Stabilizer 409 Sealing edge 410, 610Stabilizer canal 611 Stabilizer ridge 673 Stabilizer slot 675, 676Stabilizer legs 677 Stabilizer leg grooves

1. Framework for an umbrella comprising: a. A hollow pole comprising acylindrical wall having inner and outer sides having a top portion, anelongated middle portion, and a bottom portion, the outer side of thecylindrical wall having fixed thereon a slidimg rail having a top endpositioned at about the bottom of the top portion of the pole andextending vertically downward to a lower actuator arm support positionedon the pole at about the top of its bottom portion, the cylindrical wallfurther having at least one pulley opening extending from its outer sideto its inner side in the top portion of the pole above the sliding rail;b. A moveable, discontinuous cylindrical sliding sleeve having an innerside opposing the outer side of said pole, wherein a vertical channelslightly wider than said sliding rail extends along the length of thesliding sleeve, and wherein the vertical channel is aligned along saidsliding rail; c. An upper canopy support and a lower canopy support,each having a top and a bottom, each having a substantially cylindricalinner shape, and each being attached to said sliding sleeve so as tomaintain a fixed distance therebetween, wherein said sliding sleeveextends from the bottom of the inner side of the lower canopy support tothe top inner side of the upper canopy support; d. Struts, eachcomprising a long upper strut arm pivotably connected to a short lowerstrut arm, wherein each long upper strut arm has a terminal endpivotably connected to said upper canopy support, and wherein the strutsare spaced at substantially even intervals around said upper canopysupport; and wherein each lower strut arm terminates on one end at thepivot connection with its corresponding upper strut arm, and terminatesat its other end at a pivotable connection to said lower canopy support;e. An actuator comprising a lower actuator arm pivotably connected to anupper actuator arm, wherein the lower actuator arm is pivotablyconnected at one end to said lower actuator arm support and extendsoutward, and wherein the upper actuator arm has a two ends, a first endterminating at a pivotable connection to the lower actuator arm, and asecond end terminating at a pivotable connection to said upper canopysupport; f. At least one pulley system having a cable and a pulley,wherein the pulley is mounted vertically in said hollow pole and extendsoutward through said at least one pulley opening, and wherein the cablehas two ends, a first end being attached to said upper canopy support,and a second end extending over the pulley and downward into said innerside of said hollow pole; and g. At least one counterbalance weight, theat least one counterbalance weight being attached to said second end ofsaid cable in said inner side of said hollow pole.
 2. The framework ofclaim 1, wherein the upper canopy support and the lower canopy supportare reversibly fixed to said sliding sleeve.
 3. The framework of claim1, wherein the upper canopy support, the lower canopy support, and thesliding sleeve comprise a single unit.
 4. The framework of claim 3,wherein the unit is bifurcated at its mid-section, and further comprisesa sliding sleeve connector capable of maintaining a fixed distancebetween the upper canopy support and the lower canopy support of thebifurcated unit.
 5. The framework of claim 1, wherein the inner shape ofthe upper and lower canopy supports comprises a rail groove opposing thesliding rail and accepting it therein.
 6. The framework of claim 1,wherein the upper and lower canopy supports each comprise a neckextending from their bottoms, each neck having substantially the sameinner shape as its corresponding canopy support.
 7. The framework ofclaim 1, wherein the upper and lower canopy supports each comprise apair of stays on either side of the strut arms pivotably connectedthereto.
 8. The framework of claim 1, wherein the upper actuator arm ispivotably connected to the upper canopy support between a pair of stays.9. The framework of claim 6, wherein the upper actuator arm is pivotablyconnected to the neck of the upper canopy support.
 10. The framework ofclaim 1, wherein the lower canopy support is discontinuous, comprising achannel extending vertically from top to bottom for accommodating atleast one of the sliding rail and the actuator in the raised position.11. The framework of claim 10, wherein the lower actuator arm furthercomprises a channel in its topside, wherein the upper actuator arm ispivotably connected to the lower actuator arm in the lower actuator armchannel, wherein the upper actuator arm further comprises a channel inits bottomside, and wherein raising the actuator results in the slidingrail residing in the upper actuator arm channel, and the upper actuatorarm residing in the lower actuator arm channel.
 12. The framework ofclaim 1, wherein the lower actuator arm support is welded to the pole.13. The framework of claim 1, further comprising external ballastweight.
 14. The framework of claim 1, wherein the pole further comprisesa tilting mechanism
 15. The framework of claim 1, further comprising astabilizing finial having a) a plug for resting on top of the hollowpole; b) a stabilizer extending into said hollow pole, said stabilizerhaving a canal that fits around the uppermost one or more pulley's topand sides; and c) a base extending downward on the outside of said poleto shield said one or more pulley openings.
 16. The framework of claim1, further comprising a stabilizing finial having a) a plug for restingon top of the hollow pole; b) a stabilizer extending into said hollowpole, said stabilizer having two pairs of flexible legs, each pair oflegs being symmetrically opposed around an axis formed by an uppermostpulley mount extending horizontally through said pole, wherein each legcomprises a leg groove for housing the uppermost pulley mount when thestabilizer is fully inserted into said pole, and c) a base extendingdownward on the outside of said pole to shield said one or more pulleyopenings.
 17. The framework of claim 1, wherein said outer side of saidpole further comprises a lower stop tab located at said bottom of saidlower canopy support when said actuator is fully lowered.
 18. Theframework of claim 1, further comprising a base for accepting saidbottom portion of said pole.
 19. The framework of claim 1, furthercomprising a magnet on the underside outer end of said lower actuatorarm.
 20. The framework of claim 1, wherein said lower actuator armfurther comprises a fastener for maintaining said actuator in a loweredposition.
 21. The framework of claim 1, further comprising a handle onthe underside outer end of the lower actuator arm.